KR20020010938A - Method and apparatus for optimally orienting a satellite dish - Google Patents

Abstract

The present invention relates to a method and apparatus for optimally directing a satellite antenna of a satellite television system to receive signals from one or more satellites. The satellite communications system consists of a satellite antenna, a plurality of low noise block converters (LNBs), a receiver and a television. The device generates an OSD indicating the signal strength of one or more satellites. In operation, the user runs the antenna steering software on the satellite receiver and the receiver displays a graphical interface on the television screen. This interface consists of a plurality of radio buttons for each satellite. In addition, an optional embodiment of the present invention provides a third wireless button to facilitate the fine tuning process.

Description

METHOD AND APPARATUS FOR OPTIMALLY ORIENTING A SATELLITE DISH}

A satellite television system consists of a satellite antenna, a low noise block converter (LNB), a receiver and a television. The satellite antenna and the LNB are remotely located with the receiver, for example the satellite antenna and the LNB are on the roof and the receiver is in the house. The receiver generates an on-screen display (OSD) to direct the satellite antenna so that the satellite antenna faces a suitable satellite. This OSD displays the received signal strength, and a tone is generated in which the pitch of the tone varies with the magnitude of the signal strength so that one person can adjust the antenna. Therefore, the user designates the antenna and physically moves the antenna until a high tone is heard. The user then checks the magnitude of the received signal while looking at the relative signal strength, for example, a numerical indication between 0 and 100. In this way the antenna is properly aligned with the satellite.

One drawback of the original satellite television receiver system is that the antenna receives signals only from a single satellite. Recent advances in satellite television system technology use elliptical dish antennas with multiple LNBs to receive signals simultaneously from multiple satellites. However, it is very complicated to designate a satellite antenna to receive signals from multiple satellites. Until now, no method has been developed that allows consumers to optimally orient an elliptical satellite antenna to receive signals from multiple satellites.

Accordingly, there is a need for a method and apparatus for receiving signals from a plurality of satellites by optimally directing the satellite dish antenna.

The present invention relates to a satellite television system, and in particular, the present invention relates to a method and apparatus for optimally directing a satellite antenna to receive signals from a plurality of satellites.

1 is a block diagram of a satellite television system.

FIG. 2 is a diagram illustrating an OSD used to optimally direct the satellite antenna of the system of FIG. 1.

3 is a flowchart of a method for optimally directing a satellite antenna according to the present invention.

Disadvantages associated with the prior art are solved by a method and apparatus capable of optimally directing the satellite antenna of a satellite television system to receive signals from one or more satellites. The satellite television system consists of a satellite antenna, a plurality of low noise block converters (LNBs), a receiver and a television. The device forms an OSD that displays signal strength for one or more satellites. In operation, the user runs antenna oriented software on the satellite receiver and the receiver displays a graphical interactive OSD on the television screen. The display section includes a plurality of radio buttons each for each satellite. In still another embodiment of the present invention, a third radio button is provided to facilitate the " fine adjustment " process.

When the satellite radio button is selected, the first signal strength display (eg, a bar graph with a range between 0 and 100) displays the relative signal strength of the first satellite. Adjusting the altitude and inclination of the satellite antenna to signal strength To increase. When the signal strength reaches a level that locks the forward error correction (FCC) process, the text "signal is locked" is displayed in the OSD. The user then selects a second wireless button for the second satellite and resets the altitude and tilt of the satellite antenna until the signal strength associated with the second button reaches a level at which the text "Signal is locked" is displayed. Adjust Next, select the first wireless button to see if the satellite signal strength is still fixed. If the signal is not locked, the user must adjust the satellite antenna to fix the signal again. If both signals are fixed, the receiver receives and decodes satellite signals from both satellites.

Another embodiment further includes another wireless button to fine tune the satellite signal strength, for example to balance the signals so that the strength is the same between each satellite signal. In fine tuning mode, the receiver automatically selects satellites in turn. That is, the receiver switches between satellites periodically (eg, every four seconds). The user can tweak the antenna's altitude and tilt during this period to achieve maximum signal strength for each satellite.

In addition, in order to assist the user in adjusting the satellite antenna, each signal strength display generates a signal sound that increases in tone / frequency as the signal strength is increased.

The technical contents of the present invention can be easily understood from the following detailed description in conjunction with the accompanying drawings.

In order to facilitate understanding, like reference numerals refer to like elements in the drawings as much as possible.

1 is a block diagram of a satellite television system 100. The system 100 is composed of a plurality of satellites 102A and 102B, a satellite antenna 104, a plurality of low noise block converters 106A and 106B, a receiver 108 and a television 110. To direct the satellite antenna 104, the receiver 108 detects the signal strength received by the satellite antenna 104 and displays the signal strength in the graphical OSD 120 on the television 110. The user may optimally direct the satellite antenna 104 to receive signals from multiple satellites by adjusting the azimuth and tilt of the satellite antenna while monitoring the OSD 120.

Receiver 108 includes a system and subsystem for receiving and displaying programming from satellites. However, these parts of the receiver are not shown in FIG. 1 since they are not important in the present invention. The components of the receiver embodying the present invention include a signal detector 124, a central processing unit (CPU) 112, a memory 114, an I / O circuit 116, a support circuit 118, and a display. There is a generator 122. Signal detector 124 (eg, tuner) monitors the signal-to-noise ratio (SNR) of the signals received from each satellite to generate a digital value representing the SNR of the signal received by satellite antenna 104. . SNR can be considered to be proportional to the signal power received by the satellite antenna. The detected signal strength is coupled to the CPU 112 to facilitate display generation.

The CPU 112 is supported by the memory 114, the I / O circuit 116, and the support circuit 118. The memory 114 may be combined into RAM, ROM, removable storage media and mass storage devices. A software routine is stored in the memory 114 that is executed by the CPU 112 and generates an OSD that is used to facilitate satellite antenna orientation. I / O circuitry 116 provides a well-known interface that allows a user to enter information into receiver 108 via remote control. The support circuit 118 includes well known circuits such as cache, clock circuits, power supply circuits, and the like. Receiver 108 also includes a display generator 122 that generates graphics for the OSD to assist the user in directing the satellite antenna 104.

2 is a diagram illustrating an OSD 120 used to assist a user in directing a satellite antenna in a system with two satellites. The OSD 120 includes an operation selector 208, a first satellite information unit 200, a second satellite information unit 202, a fine tuning information unit 204, and a satellite position information unit 206.

The operation selector 208 includes a series of selectable buttons that facilitate input of information to the receiver. Button selection is implemented through control devices such as infrared remote control, front panel buttons, wireless keyboard and mouse. The button 210 relates to an input screen that asks the user to select the type of satellite antenna to use, such as a multiple satellite antenna or a single satellite antenna. If the user selects a satellite antenna capable of receiving signals only from a single satellite, the prior art coordination display for the single satellite is displayed to the user. An OSD 120 is also possible for selecting multiple satellites.

To determine the approximate position of the satellite over the air, the user must enter his position. The location of the user can be entered by entering the user's postal code, city name or latitude and longitude. This information is entered by selecting one of the buttons 212, 214, 216 and entering the requested information.

Once all the information has been entered, the user selects the signal meter button 218 to return to the OSD 120. The receiver uses the user's location information to retrieve from the table the approximate location of the centerline between the two satellites above the user's location. This center line position information is displayed in the satellite position information unit 206. The user can use this information to initially direct the antenna to the approximate direction of the satellite. To assist the user, a slope (relative to the horizontal line) and an altitude scale are drawn on the satellite antenna mounting bracket.

In order to direct the antenna correctly, the user selects the satellite radio button 220 or 222 associated with the satellite information 200 or 202. The satellite information 220 or 222 includes signal strength meters, numerical current signal strength values, peak current strength values, transponder identification numbers, and signal fixation indicator text. The operation of these parts of the OSD will be described in FIG. 3 below. Each part can be said to fix the signal while adjusting the altitude and tilt of the satellite antenna.

Once the signal is fixed, the user can optionally select the fine tuning wireless button 224 to activate the fine tuning process. Each satellite is automatically selected in turn by a fine tuning processor. This shift is made every four seconds, for example. As the information section of each satellite is active, the user can adjust the orientation of the antenna to optimize the signal strength for the "operating" satellite. By repeatedly adjusting the antenna orientation, the signal strength can be optimal for both satellites.

3 is a flow diagram of a process 300 for optimally directing a satellite antenna in accordance with the present invention. Process 300 begins at step 302 and continues to step 304. In step 304, the user selects the type of satellite antenna to be used, namely single or multiple satellite antennas. If the antenna is a single satellite antenna, a prior art single satellite antenna directing process 306 is started. If the antenna is a multi-satellite antenna, the process of steps 304 to 308 begins. In step 308, the user is asked to enter his location information, such as zip code, city name or latitude / longitude. In step 310, the user selects a signal meter button. In step 312, the user selects a satellite radio button associated with one of the satellites. In step 314, the user adjusts the orientation of the antenna to increase the signal strength of the signal strength display. This adjustment continues until the satellite information points to signal fixation. In order to support antenna adjustment by one user, the receiver generates a beeping sound with rising frequency or tone as the signal strength increases. As such, the user can adjust the antenna without looking directly at the display.

In step 316, process 300 queries whether the antenna is directed for all satellites so that all signals from the satellites are fixed. If the antenna has to be adjusted for another satellite, the routine begins at step 312 of selecting a radio button of another satellite and the antenna is adjusted until the signal is fixed.

Once all satellite signals have been fixed, the user continues to adjust the antenna and terminates the process along path 326 in an attempt to maximize the signal strength received from each satellite using the processes of steps 312, 314, and 316. The original user attempts to achieve "best compromise" between the signals. However, another embodiment of the present invention automates this with a "fine adjustment" process. To begin the fine tuning process, the user selects the fine tuning radio button in step 318 and the process 300 continues to step 320. In step 320, the process is periodically switched between satellite information units, and in step 322 the user adjusts the antenna. The process switches between satellites, eg every four seconds. Therefore, the user can adjust the antenna to maximize the signal strength of one satellite for four seconds until the signal strength received from all satellites is optimized and the signal strength of the next satellite is maximum for the next four seconds. The process ends at step 324.

In summary, the present invention provides a method and apparatus for directing a satellite antenna of a satellite television system capable of receiving signals from a plurality of satellites.

Although various embodiments including the technical details of the present invention have been introduced and described herein, those skilled in the art will be able to easily devise embodiments having the above description and other parts changed.

Claims (11)

A method of directing a satellite antenna to receive signals from a plurality of satellites, the method comprising: Generating an OSD comprising a signal strength meter of each of the satellites; Selecting a particular satellite from the satellite menu; Adjusting the altitude and tilt of the satellite antenna while monitoring the signal strength meter of the selected satellite; and Selecting another satellite and adjusting the satellite antenna while monitoring the signal strength meter of the selected satellite. The method of claim 1, Determining when the antenna is directed such that the receiver can achieve signal fixation for the signals of all satellites; and And automatically switching between satellites while further directing the satellite antenna. 3. The method of claim 2, wherein automatically switching between satellites periodically switches between satellites. An apparatus for directing a satellite antenna to receive signals from a plurality of satellites, the apparatus comprising: Means for generating an OSD including a signal strength meter for each of the satellites; Means for selecting a particular satellite from the satellite menu; Means for adjusting the altitude and tilt of the satellite antenna while monitoring the signal strength meter of the selected satellite; Means for adjusting the satellite antenna while selecting another satellite and monitoring the signal strength meter of the selected satellite. The method of claim 4, wherein the method Means for determining when the antenna is directed such that the receiver can achieve signal fixation for signals of all satellites; And means for automatically switching between satellites while further directing the satellite antenna. 6. The satellite antenna directing device of claim 5 wherein the means for automatically switching between satellites periodically switches between satellites. And a plurality of selectable satellite information portions, each portion comprising a signal strength meter. 8. The OSD of claim 7, wherein each of the portions further comprises a signal lock indicator. The method of claim 7, wherein The OSD further comprising a selectable fine adjustment. The method of claim 7, wherein An OSD further comprising satellite location information indicating centerline orientation between available satellites. The method of claim 7, wherein And an OSD further comprising an information input portion.